Fairfield University DigitalCommons@Fairfield Biology Faculty Publications Biology Department 1-1-2005 The effect of farnesol on amino acid incorporation by a wild-type and cell-wall variant strain of Candida albicans Phyllis C. Braun Fairfield University, pcbraun@fairfield.edu Copyright National Research Council Research Press 2005. Published version available at: http://nrcresearchpress.com/doi/pdf/10.1139/w05-050 Peer Reviewed Repository Citation Braun, Phyllis C., "The effect of farnesol on amino acid incorporation by a wild-type and cell-wall variant strain of Candida albicans" (2005). Biology Faculty Publications. 11. http://digitalcommons.fairfield.edu/biology-facultypubs/11 Published Citation Braun PC. 2005. The effect of farnesol on amino acid incorporation by a wild-type and cell-wall variant strain of Candida albicans. Canadian Journal of Microbiology 51(8): 715-718 This Article is brought to you for free and open access by the Biology Department at DigitalCommons@Fairfield. It has been accepted for inclusion in Biology Faculty Publications by an authorized administrator of DigitalCommons@Fairfield. For more information, please contact digitalcommons@fairfield.edu.
1 2 3 4 5 The Effect of Farnesol on Amino Acid Incorporation by Wild-Type and Cell-Wall Variant Strain of Candida albicans 6 7 Phyllis C. Braun, PhD 8 9 10 11 12 13 14 15 16 17 18 19 20 21 Address Correspondence to: Phyllis C. Braun, PhD Biology Department Fairfield University 1073 North Benson Road Fairfield, CT 06824 U.S.A. pcbraun@mail.fairfield.edu 22 1
23 ABSTRACT 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 Cell-surface hydrophobicity has been shown to be an important factor in the ability of C. albicans to adhere to host tissue and in determining its resistance to phagocytic killing. Farnesol was recently identified as a quorum-sensing molecule that inhibits mycelial development in this organism. In this study, C. albicans A9 (wild type) and V10 (cell-wall variant strain) were used. Previous experiments have indicated that A9-WT organisms have hydrophilic cell walls, while A9-V10 exhibits hydrophobic cell surfaces when both are grown in Yeast Nitrogen Broth (without amino acids) supplemented with 2% glucose at 37 C. The effect of farnesol on the incorporation of arginine, aspartic acid, glycine, histidine, leucine, and serine was studied in wildtype and cell-wall variant strains under these conditions. It was determined that both strains incorporated significantly greater amounts of all amino acids tested, except for glycine, as the concentration of farnesol increased to 10 ug/ml. Farnesol concentrations greater than 10 ug/ml abolished the enhanced effects of amino acid transport in both strains of C. albicans. In addition, it was determined that farnesoltreated A9-V10 hydrophobic cell surface organisms had increased amino acid uptake compared with the hydrophilic A9-WT strain although the magnitude of the effect (% increase) varied depending on the amino acid studied. 42 43 (Key Words: Candida albicans, farnesol, amino acid incorporation) 2
44 45 46 47 48 49 50 51 52 53 54 Candida species are ubiquitous fungi and the most common fungal pathogens affecting humans. C. albicans is the primary etiologic agent of candidiasis, a disease that can vary from superficial mucosal lesions in the immunocompetent host to systemic or disseminated infection in the immunocompromised individual (Odds 1988; Ahearn 1978). The cell wall of the organism is important to its success as a pathogen (Odds 1985) because it is required for growth; provides rigidity and protection against osmotic insult; and is the site of contact between the organism and its surroundings. Survival of C. albicans in its environment is dependent on the transport of nutrients into the organism. For molecules to enter, they must first pass through the cell wall and then the plasma membrane, a limiting structure between the cell wall and the cytoplasm that acts as a permeability barrier to many solutes. 55 56 57 58 59 60 61 62 63 64 65 66 67 The molecular complexity of the C. albicans cell wall is well known. The cell wall is a heterogeneous structure composed predominantly of polysaccharides (mainly mannan, glucan, and chitin), proteins, and lipids (Calderone and Braun 1991; Odds 1985). The proteins located on the external surface of C. albicans are composed of high molecular-weight mannoproteins, and constitute the outer fibrillar layer of the cell wall. These mannoproteins are regarded as important sites that influence amino acid transport by this organism (Braun 1999). Investigators have observed that the presence of fibrillar mannoproteins determines the hydrophilic nature of C. albicans cells (Glee et al. 1995; Hazen and Hazen 1992). Any changes in the length or concentration of mannoprotein fibrils, or decrease in the amount of phosphodiester-linked, acid-labile mannosyl-groups results in a hydrophobic cell surface (Masuoka and Hazen 1997). 68 3
69 70 71 72 73 74 75 Farnesol (C 15 H 26 O), a recently discovered extracellular quorum-sensing molecule produced by C. albicans, blocks yeast-to-mycelium conversion when it accumulates above threshold levels. Farnesol is a hydrophobic molecule that alters cell morphology but does not alter growth rate. It is produced at all growth temperatures, and is produced continuously during growth of C. albicans (Hornby et al. 2001). Inhibition of C. albicans biofilm formation by farnesol also has been reported (Ramage et al. 2002). 76 77 78 79 80 81 82 83 84 85 The purpose of this study was to determine how amino acid incorporation was influenced by exogenous supplements of farnesol. Any changes in nutrient transport due to farnesol presence would affect the growth and presumably the pathogenesis of this organism. Two strains of C. albicans were used. When grown in amino-acid deficient Yeast Nitrogen Broth (YNB) supplemented with 2% glucose, the wild-type strain of C. albicans (A9-WT) exhibits hydrophobic cell surfaces at 23 C and the typical hydrophilic morphology at 37 C. The cell wall variant (A9-V10) however, displays cell-surface hydrophobicity under all growth conditions (Masuoka and Hazen 1997). 86 87 88 89 90 91 92 C. albicans A9-WT and A9-V10 were maintained on brain-heart infusion slants at 4 C. The two strains were grown to mid-stationary phase in YNB buffered with 0.05-M sodium phosphate (ph 7.2) and supplemented with 2% (w/v) glucose (YNB+G) at either 23 C or 37 C to induce hydrophobic or hydrophilic cell wall conditions. Cells were washed and resuspended in PB (sodium phosphate buffer, 0.05 M, ph 7.2) and kept on ice. 93 4
94 95 96 97 98 99 100 101 102 Cell-surface hydrophobicity (CSH) of the culture was determined by using the polystyrene microsphere assay (Hazen and Hazen 1988). A working 10% solution was prepared by placing 6 ml of stock microspheres (diameter, 0.825 um; Sigma Chemical Co.). into 2.0 ml of PB, and kept on ice. The assay was performed by mixing equal volumes (l00 ml) of washed yeast cells (5 x 10 7 cells per ml) and microspheres in polypropylene test tubes and incubating the mixture for 2 min at room temperature. The mixtures were vortexed subsequently for 30 s, and microscope slides were prepared. Cultures were determined to exhibit CSH when 95% of the population had more than three attached microspheres. 103 104 105 106 107 Yeast cells were resuspended in 1 ml of sterile YNB+G at a concentration of 5 x 10 7 cells per ml. Triplicate samples were incubated with 0, 1, or 10 micrograms of free farnesol (Sigma; trans, trans-farnesol) for 10 minutes at 37 C. Subsequently, [ 3 H] L-amino acids ([2,3-3 H]arginine, specific activity 36.8 Ci/mmol; [2,3-108 3 H]aspartic acid, specific activity 15.5 Ci mmol -1 ; [2-3 H]glycine, specific activity 109 43.8 Ci mmol -1 ; [2,5-3 H]histidine, specific activity 50.4 Ci mmol -1 ; [4,5-3 H]leucine, 110 111 112 113 114 115 116 117 specific activity 52 Ci mmol -1 ; [3-3 H]serine, specific activity 21.7 Ci mmol -1 ; New England Nuclear), were individually assayed by adding the radioactively labelled substance, 1 uci ml -1 to the cultures These cultures were further incubated for 1 h at 37 C (100 rpm). Incorporation of radiolabel was stopped by the immediate addition of 1 ml of 15% TCA. The suspensions were filtered through Whatman GF/A glass fiber filters, and the precipitate remaining on each filter was washed twice with 15% TCA and once with 95% ethanol. The filters were dried and transferred to scintillation vials, and the radioactivity was counted in ScintiSafe-LSC Cocktail. 118 5
119 120 121 122 Dry weights were determined by filtering 1-mL (5 x 10 7 cells) samples on pretared Whatman filters. These filters were washed with distilled water, dried, and weighed. Uptake of the radiolabeled nutrient is expressed as the number of picomoles incorporated per milligram of dry weight. 123 124 125 126 127 Statistical variables used to analyze the data included mean value, standard error of the mean, and two-tailed Student s t-test results. When two groups were compared, a P-value of less than 0.05 was considered to indicate a significant difference between the groups. 128 129 130 131 132 133 134 135 To determine whether A9-WT and A9-V10 strains had different growth patterns in YNB, 24-hour growth curves were performed. Calculations of the mean growth rate constant (k) indicated insignificant differences between wild-type and cell-wall variant at 23 C or 37 C, respectively. The mean generation time (g) also indicated very little growth difference between these strains at the experimental temperatures. There was, however, a significant difference in the growth rate constant and generation time for each strain at the two different temperatures (Table 1). 136 137 138 139 140 141 142 143 Incubation at 37 C of stationary-phase, farnesol-untreated cultures with the [ 3 H] amino acid demonstrated that A9-V10, possessing CSH, preferentially incorporated more of the individually tested nutrient than A9-WT with a hydrophilic surface (Figures 1 and 2). Amino acid incorporation was linear in both strains up to 60 minutes (data not shown). However, the percentage of increase varied according to the amino acid, with A9-V10 incorporating 5% more aspartic acid and leucine, 11% more arginine, and 30% more histidine and serine than A9-WT. Experimental 6
144 145 146 147 148 149 150 151 152 153 154 155 156 157 results indicated A9-WT and A9-V10 cultures were unable to transport glycine under the described conditions (data not shown). Incorporation of arginine, histidine, leucine, and serine by both A9-WT and A9-V10 was further enhanced by the presence of 1 or 10 ug of farnesol compared to untreated. However, the magnitude of the effect of farnesol on transport by A9-WT and A9-V10 was dependent on the amino acid studied (Table 2). Aspartic acid incorporation also was enhanced by farnesol treatment; however, 10 µg of farnesol increased A9-WT incorporation to 1.1 picomoles per mg dry weight, and A9-V10 incorporation to 1.8 picomoles per mg dry weight from the untreated baseline of 0.76 and 0.8 picomoles per mg dry weight, respectively. Farnesol concentrations greater than 10 ug/ml reduced the incorporation and presumably the transport of all amino acids tested. Increased farnesol concentrations (up to 100 ug) abolished the augmented effects of the lower concentrations. Amino acid incorpoation at these higher concentrations was reduced to base-line (0 ug farnesol) in both strains of C. albicans (data not shown). 158 159 160 161 162 163 164 165 166 167 168 The role of the microenvironment apparently has a very important role in determining the pathogenicity of C. albicans. Farnesol, which is produced in situ by C. albicans, affects nutrient transport. This discovery may be relevant during in vivo infections. The results of these experiments indicate that very limited micromolar amounts of farnesol increased amino acid incorporation by this organism. The exact nature of the interaction of farnesol with C. albicans is not understood; however, the hydrophobic A9-V10 appears to exhibit greater nutrient transport than the A9-WT strain. This is likely a result of the lipophilic properties of farnesol, which probably enables more effective binding of this compound to a receptor site on the cell 7
169 170 171 172 173 174 175 176 177 178 179 180 membrane. Presumably, an increase in nutrient transport affects the growth, metabolism, and virulence of C. albicans and the morphological transformation from yeast to mycelia (a crucial step in the pathogenesis of C. albicans). This study demonstrates that as farnesol concentrations increased, the initial incorporation enhancement was diminished to control levels (0 µg farnesol). These results indicate a gradient effect produced by farnesol that influences metabolic activities of this organism. These results, as well as previous investigations that have shown that farnesol prevents biofilm formation (Ramage et al. 2002) and inhibits mycelial development in a quorum-sensing manner (Hornby et al. 2001) suggests that farnesol might be the first of a new class of antifungal compounds. In addition, Hornby et al. (2003) recently reported that compounds that block sterol biosynthesis in C. albicans caused an increase in intracellular and extracellular 181 farnesol levels. Farnesol would not kill this organism and upset the balance of the 182 183 184 185 186 normal flora in an individual. Instead, the metabolism of C. albicans would be affected which ultimately controls morphogenesis. Farnesol would limit C. albicans growth to the yeast form and in so doing restrict pathogenesis in its host. Further studies on the effect of farnesol on C. albicans are needed to strengthen its role as a therapeutic agent. 187 188 189 8
REFERENCES Ahearn, D.G. 1978. Medically important yeasts. Annu. Rev. Microbiol. 32:59-68. Braun, P.C. 1999. Nutrient uptake by Candida albicans: the influence of cell surface mannoproteins. Can. J. Microbiol. 45:353-359. Calderone, R.A., Braun, P.C. 1991. Adherence and receptor relationships of Candida albicans. Microbiol. Rev. 55:1-20. Glee, P.M., Sundstrom, P., Hazen, K.C. 1995. Expression of surface hydrophobic proteins by Candida albicans in vivo. Infect. Immun. 63:1373-1379. Hazen, B.W. and Hazen, K.C. 1988. Dynamic expression of cell surface hydrophobicity during initial yeast cell growth and before germ tube formation of Candida albicans. Infect. Immun. 56:2521-2525. Hazen, K.C. and Hazen, B.W. 1992. Hydrophobic surface protein masking by the opportunistic fungal pathogen Candida albicans. Infect. Immun.60:1499-1508. Hornby, J.M., Jensen, E.C., Lisec, A.D., Testo, J.J., Jahnke, B., Shoemaker, R., Dussault, P.,Nickerson, K.W. 2001. Quorum sensing in the dimorphic fungus Candida albicans is mediated by farnesol. Appl. Environ. Microbiol. 67:2982-2992.
Hornby, J.M., Kebaara, B.W., Nickerson, K.W. 2003. Farnesol biosynthesis in C. albicans: Cellular response to sterol inhibition by zaragozic acid B. Antimicrob. Agents Chemother. 47:2366-2369. Masuoka, J., Hazen, K.C. 1997. Cell wall protein mannosylation determines Candida albicans cell surface hydrophobicity. Microbiology.143:3015-3021. Odds, F.C. 1988. Candida and Candidosis. W.B. Sanders, London. Odds, F.C. 1985. Morphogenesis in Candida albicans. Crit. Rev. Microbiol.12:45-93. Ramage, G., Saville, S.P., Wickes, B.L., Lopez-Ribot, J.L. 2002. Inhibition of Candida albicans biofilm formation by farnesol, a quorum-sensing molecule. Appl. Environ. Microbiol. 68:5459-5463. 2
Acknowledgement P.C.B. is grateful for the lively discussions and editorial assistance of John Zoidis and the excellent technical assistance of Elizabeth Vancza and Lisa Runco. 3
Table 1. Mean Growth Rate Constant (k) and Mean Generation Time (g) for C. albicans Strains A9-WT and A9-V10 Grown at 23 C and 37 C. A9-WT A9-V10 23 C 37 C 23 C 37 C k 0.3479 0.7262 0.4592 0.7573 g (hours) 2.874 1.377 2.177 1.320 A9-WT and A9-V10 cultures were grown for 24 hours in YNB plus 2% glucose broth. Values represent the average of 5 experimental growth curves. Data were analyzed using Student s t-test. When growth comparisons were determined, a P-value less than 0.05 was considered to indicate a significant difference between the groups. 4
Table 2. Magnitude of Effect (% Increase) of Farnesol 1 µg and 10 µg on Amino Acid Transport by C. albicans Strains A9-WT and A9-V10. A9-WT A9-V10 Farnesol Farnesol Farnesol Farnesol 1 µg 10 µg 1 µg 10 µg Arginine 2 26 4 19 Histidine 14 23 10 21 Leucine 21 42 22 55 Serine 44 54 33 90 5
Figure 1 6
Figure 2 7
8
Legend 9
Figs. 1-2: Incorporation of four different L-[ 3 H] amino acids by pretreated farnesol C. albicans strains A9-WT(hydrophilic) and A9-V10 (hydrophobic) was determined after a 1 h incubation at 37 C. Values represent the SEM of triplicate samples from several experiments (n=6). Student s t test was used to analyze the data. When incorporation comparisons between cell strains for a particular amino acid was determined, a P< 0.05 was considered to indicate a significant difference between groups. 10